/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #define COMPONENT_TRANSFER_IDENTITY 0 #define COMPONENT_TRANSFER_TABLE 1 #define COMPONENT_TRANSFER_DISCRETE 2 #define COMPONENT_TRANSFER_LINEAR 3 #define COMPONENT_TRANSFER_GAMMA 4 // Must be kept in sync with `Filter::as_int` in internal_types.rs // Not all filters are defined here because some filter use different shaders. #define FILTER_CONTRAST 0 #define FILTER_GRAYSCALE 1 #define FILTER_HUE_ROTATE 2 #define FILTER_INVERT 3 #define FILTER_SATURATE 4 #define FILTER_SEPIA 5 #define FILTER_BRIGHTNESS 6 #define FILTER_COLOR_MATRIX 7 #define FILTER_SRGB_TO_LINEAR 8 #define FILTER_LINEAR_TO_SRGB 9 #define FILTER_FLOOD 10 #define FILTER_COMPONENT_TRANSFER 11 #ifdef WR_VERTEX_SHADER void SetupFilterParams( int op, float amount, int gpu_data_address, out vec4 color_offset, out mat4 color_mat, out highp int table_address ) { float lumR = 0.2126; float lumG = 0.7152; float lumB = 0.0722; float oneMinusLumR = 1.0 - lumR; float oneMinusLumG = 1.0 - lumG; float oneMinusLumB = 1.0 - lumB; float invAmount = 1.0 - amount; if (op == FILTER_GRAYSCALE) { color_mat = mat4( vec4(lumR + oneMinusLumR * invAmount, lumR - lumR * invAmount, lumR - lumR * invAmount, 0.0), vec4(lumG - lumG * invAmount, lumG + oneMinusLumG * invAmount, lumG - lumG * invAmount, 0.0), vec4(lumB - lumB * invAmount, lumB - lumB * invAmount, lumB + oneMinusLumB * invAmount, 0.0), vec4(0.0, 0.0, 0.0, 1.0) ); color_offset = vec4(0.0); } else if (op == FILTER_HUE_ROTATE) { float c = cos(amount); float s = sin(amount); color_mat = mat4( vec4(lumR + oneMinusLumR * c - lumR * s, lumR - lumR * c + 0.143 * s, lumR - lumR * c - oneMinusLumR * s, 0.0), vec4(lumG - lumG * c - lumG * s, lumG + oneMinusLumG * c + 0.140 * s, lumG - lumG * c + lumG * s, 0.0), vec4(lumB - lumB * c + oneMinusLumB * s, lumB - lumB * c - 0.283 * s, lumB + oneMinusLumB * c + lumB * s, 0.0), vec4(0.0, 0.0, 0.0, 1.0) ); color_offset = vec4(0.0); } else if (op == FILTER_SATURATE) { color_mat = mat4( vec4(invAmount * lumR + amount, invAmount * lumR, invAmount * lumR, 0.0), vec4(invAmount * lumG, invAmount * lumG + amount, invAmount * lumG, 0.0), vec4(invAmount * lumB, invAmount * lumB, invAmount * lumB + amount, 0.0), vec4(0.0, 0.0, 0.0, 1.0) ); color_offset = vec4(0.0); } else if (op == FILTER_SEPIA) { color_mat = mat4( vec4(0.393 + 0.607 * invAmount, 0.349 - 0.349 * invAmount, 0.272 - 0.272 * invAmount, 0.0), vec4(0.769 - 0.769 * invAmount, 0.686 + 0.314 * invAmount, 0.534 - 0.534 * invAmount, 0.0), vec4(0.189 - 0.189 * invAmount, 0.168 - 0.168 * invAmount, 0.131 + 0.869 * invAmount, 0.0), vec4(0.0, 0.0, 0.0, 1.0) ); color_offset = vec4(0.0); } else if (op == FILTER_COLOR_MATRIX) { vec4 mat_data[4] = fetch_from_gpu_cache_4(gpu_data_address); vec4 offset_data = fetch_from_gpu_cache_1(gpu_data_address + 4); color_mat = mat4(mat_data[0], mat_data[1], mat_data[2], mat_data[3]); color_offset = offset_data; } else if (op == FILTER_COMPONENT_TRANSFER) { table_address = gpu_data_address; } else if (op == FILTER_FLOOD) { color_offset = fetch_from_gpu_cache_1(gpu_data_address); } } #endif #ifdef WR_FRAGMENT_SHADER vec3 Contrast(vec3 Cs, float amount) { return clamp(Cs.rgb * amount - 0.5 * amount + 0.5, 0.0, 1.0); } vec3 Invert(vec3 Cs, float amount) { return mix(Cs.rgb, vec3(1.0) - Cs.rgb, amount); } vec3 Brightness(vec3 Cs, float amount) { // Apply the brightness factor. // Resulting color needs to be clamped to output range // since we are pre-multiplying alpha in the shader. return clamp(Cs.rgb * amount, vec3(0.0), vec3(1.0)); } // Based on the Gecko's implementation in // https://hg.mozilla.org/mozilla-central/file/91b4c3687d75/gfx/src/FilterSupport.cpp#l24 // These could be made faster by sampling a lookup table stored in a float texture // with linear interpolation. vec3 SrgbToLinear(vec3 color) { vec3 c1 = color / 12.92; vec3 c2 = pow(color / 1.055 + vec3(0.055 / 1.055), vec3(2.4)); return if_then_else(lessThanEqual(color, vec3(0.04045)), c1, c2); } vec3 LinearToSrgb(vec3 color) { vec3 c1 = color * 12.92; vec3 c2 = vec3(1.055) * pow(color, vec3(1.0 / 2.4)) - vec3(0.055); return if_then_else(lessThanEqual(color, vec3(0.0031308)), c1, c2); } // This function has to be factored out due to the following issue: // https://github.com/servo/webrender/wiki/Driver-issues#bug-1532245---switch-statement-inside-control-flow-inside-switch-statement-fails-to-compile-on-some-android-phones // (and now the words "default: default:" so angle_shader_validation.rs passes) vec4 ComponentTransfer(vec4 colora, vec4 vfuncs, highp int table_address) { // We push a different amount of data to the gpu cache depending on the // function type. // Identity => 0 blocks // Table/Discrete => 64 blocks (256 values) // Linear => 1 block (2 values) // Gamma => 1 block (3 values) // We loop through the color components and increment the offset (for the // next color component) into the gpu cache based on how many blocks that // function type put into the gpu cache. // Table/Discrete use a 256 entry look up table. // Linear/Gamma are a simple calculation. // Both offset and k must be marked as highp due to a Adreno 3xx bug likely // to do with converting between precisions (as they would otherwise be // promoted when adding to table_address). highp int offset = 0; highp int k; vec4 texel; // Dynamically indexing a vector is buggy on some platforms, so use a temporary array int[4] funcs = int[4](int(vfuncs.r), int(vfuncs.g), int(vfuncs.b), int(vfuncs.a)); for (int i = 0; i < 4; i++) { switch (funcs[i]) { case COMPONENT_TRANSFER_IDENTITY: break; case COMPONENT_TRANSFER_TABLE: case COMPONENT_TRANSFER_DISCRETE: { // fetch value from lookup table k = int(floor(colora[i]*255.0 + 0.5)); texel = fetch_from_gpu_cache_1(table_address + offset + k/4); colora[i] = clamp(texel[k % 4], 0.0, 1.0); // offset plus 256/4 blocks offset = offset + 64; break; } case COMPONENT_TRANSFER_LINEAR: { // fetch the two values for use in the linear equation texel = fetch_from_gpu_cache_1(table_address + offset); colora[i] = clamp(texel[0] * colora[i] + texel[1], 0.0, 1.0); // offset plus 1 block offset = offset + 1; break; } case COMPONENT_TRANSFER_GAMMA: { // fetch the three values for use in the gamma equation texel = fetch_from_gpu_cache_1(table_address + offset); colora[i] = clamp(texel[0] * pow(colora[i], texel[1]) + texel[2], 0.0, 1.0); // offset plus 1 block offset = offset + 1; break; } default: // shouldn't happen break; } } return colora; } void CalculateFilter( vec4 Cs, int op, float amount, highp int table_address, vec4 color_offset, mat4 color_mat, vec4 v_funcs, out vec3 color, out float alpha ) { // Un-premultiply the input. alpha = Cs.a; color = alpha != 0.0 ? Cs.rgb / alpha : Cs.rgb; switch (op) { case FILTER_CONTRAST: color = Contrast(color, amount); break; case FILTER_INVERT: color = Invert(color, amount); break; case FILTER_BRIGHTNESS: color = Brightness(color, amount); break; case FILTER_SRGB_TO_LINEAR: color = SrgbToLinear(color); break; case FILTER_LINEAR_TO_SRGB: color = LinearToSrgb(color); break; case FILTER_COMPONENT_TRANSFER: { // Get the unpremultiplied color with alpha. vec4 colora = vec4(color, alpha); colora = ComponentTransfer(colora, v_funcs, table_address); color = colora.rgb; alpha = colora.a; break; } case FILTER_FLOOD: color = color_offset.rgb; alpha = color_offset.a; break; default: // Color matrix type filters (sepia, hue-rotate, etc...) vec4 result = color_mat * vec4(color, alpha) + color_offset; result = clamp(result, vec4(0.0), vec4(1.0)); color = result.rgb; alpha = result.a; } } #endif